Chemoenzymatic Cascades Combining Biocatalysis and Transition Metal Catalysis for Asymmetric Synthesis

González‐Granda, Sergio; Escot, Lorena; Lavandera, Iván; Gotor‐Fernández, Vicente

doi:10.1002/ange.202217713

Cited by 7 publications

(3 citation statements)

References 148 publications

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“…The main advantage of this strategy is that it enables the construction of synthetic complexity with simpler setups. (45)(46)(47)(48)(49) With our broad experience in the construction of chemoenzymatic cascades by merging chemical and enzyme catalysis, (46,50,51) and considering the mild reaction conditions of the L-Cysmediated alkyne hydration, we envisaged that the organocatalytic reaction could be combined with an enzyme-mediated asymmetric reduction process to access chiral β-hydroxy sulfones, which are important building blocks in the synthesis of different APIs such as apremilast and bicalutamide. Based on our previous report on the chemoenzymatic oxosulfonylation-bioreduction process combining catalytic amounts of FeCl3 and ketoreductases (KREDs), (52) several KREDs from commercial sources and our in-house collection were selected and explored for the one-pot concurrent process, in which all reaction components are added at once.…”

Section: A Chemoenzymatic Cascade To Access Chiral β-Hydroxy Sulfonesmentioning

confidence: 99%

Organocatalytic hydration of activated alkynes

González-Rodríguez,

González-Granda,

Lavandera

et al. 2024

Preprint

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Hydration reactions consist of the introduction of a molecule of water into a chemical compound. This process is a particularly useful method to allow, for instance, the conversion of alkynes into carbonyls, which are strategic intermediates in the synthesis of a plethora of compounds. Herein we demonstrate that L-cysteine can catalyse the hydration of activated alkynes in a very effective and fully regioselective manner to access β-ketosulfones, amides and esters in aqueous conditions. The mild reaction conditions facilitated the integration with enzyme catalysis to access chiral β-hydroxy sulfones from the corresponding alkynes in a one-pot cascade process in good yields and excellent enantiomeric excess. These findings pave the way towards establishing a general method for metal-free, cost-effective, and more sustainable alkyne hydration processes

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Section: A Chemoenzymatic Cascade To Access Chiral β-Hydroxy Sulfonesmentioning

confidence: 99%

Organocatalytic hydration of activated alkynes

González-Rodríguez,

González-Granda,

Lavandera

et al. 2024

Preprint

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“…However, recent innovations from our own research group and others have demonstrated that, in contrast with the aforementioned conventional wisdom, polar s ‐block organometallic RLi reagents can be used: i ) under air; ii ) in sustainable, protic, non‐toxic and non‐dried solvents [like deep eutectic solvents or even water]; and iii ) at room temperature and under air/moisture [7–14] . Consequently, this paradigm shift in organolithium chemistry illustrates the capability of RLi reagents to operate under conditions compatible with other catalysts, such as enzymes, thus opening new avenues to the design of chemoenzymatic cascades [15–24] …”

Section: Introductionmentioning

confidence: 99%

“…[7][8][9][10][11][12][13][14] Consequently, this paradigm shift in organolithium chemistry illustrates the capability of RLi reagents to operate under conditions compatible with other catalysts, such as enzymes, thus opening new avenues to the design of chemoenzymatic cascades. [15][16][17][18][19][20][21][22][23][24] The traditional challenge in transformations involving organolithium compounds and enzymes is that they typically rely on tedious multistep and energy/time consuming protocols in which intermediate isolation/ purification steps or compartmentalization of the different synthetic systems is required. [25] In some cases, these hybrid reactions RLi/enzyme have been successfully conducted sequentially in a one-pot manner.…”

Section: Introductionmentioning

confidence: 99%

Merging Organolithium Chemistry and Stereoselective Biocatalysis: Transformation of Aromatic Nitriles into Chiral Alcohols

Ríos‐Lombardía,

Morís‐Menéndez,

Lavandera

et al. 2024

Adv Synth Catal

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The combination of RLi‐mediated organic transformations (under air and at room temperature) with a subsequent stereoselective biocatalytic reaction is for the first time presented. Most of the previous asymmetric chemoenzymatic routes have been limited to the concomitant or sequential combination of transition metals/organocatalysts with enzymes. However, the use of polar organometallic reagents (RLi) in the design of these stereoselective hybrid protocols has been totally neglected, as far as we are concerned. Thus, in this work, the combination of organolithium chemistry and asymmetric biocatalysis is described for the first time in a one‐pot fashion. The chemoenzymatic approach converts a series of nitriles into chiral alcohols consisting of two steps, where the key item was the finding of suitable conditions to adapt the reactivities of organolithiums and alcohol dehydrogenases (ADHs) in the same recipient. The organolithium addition occurred with total chemoselectivity (no side reactions were observed) under neat conditions and room temperature leading to the corresponding imines, which were hydrolyzed using a buffer, and adjusting the pH for the subsequent ADH action. Commercial and made in house overexpressed ADHs allowed to produce chiral alcohols with excellent selectivities and good overall yields. The different behavior displayed for the reductive enzymes in the presence of diethyl ether clearly influenced in the decision to let the organolithium solvent evaporate under open‐air conditions before developing the bioreduction step. Our results demonstrate the importance of the fine orchestration of the reaction conditions for the development of efficient hybrid chemoenzymatic cascades without the need of intermediate isolation/purification steps or compartmentalization of the different synthetic systems.

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Design von 3D‐gedruckten heterogenen Reaktorsystemen zur Überwindung von Inkompatibilitätshürden bei der Kombination von Metall‐ und Enzym‐Katalyse in einem Eintopf‐Prozess

Salitra,

Gurauskis,

Gröger

2024

Angewandte Chemie

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Combining chemo‐ and biocatalysis enables the design of novel economic and sustainable one‐pot processes to industrial chemicals, preferably proceeding in water. While a range of proof‐of‐concepts for the compatibility of such catalysts from these two different “worlds of catalysis” have recently been demonstrated, merging non‐compatible chemo‐ and biocatalysts for joint applications within one reactor remained a challenge. A conceptual solution is compartmentalization of the catalytic moieties by heterogenization of critical catalyst components, thus “shielding” them from the complementary non‐compatible catalyst, substrate or reagent. Exemplified for a one‐pot process consisting of a metal‐catalyzed Wacker oxidation and enzymatic reduction as non‐compatible individual reactions steps, we demonstrate that making use of 3D‐printing of heterogeneous materials containing Cu as critical metal component can overcome such incompatibility hurdles. The application of a 3D‐printed Cu‐ceramic device as metal catalyst component allows an efficient combination with the enzyme and the desired two‐step transformation of styrene into the chiral alcohol product with high overall conversion and excellent enantioselectivity. This compartmentalization concept based on 3D‐printing of heterogenized metal catalysts represents a scalable methodology and opens up numerous perspectives to be used as a general tool also for other related chemoenzymatic research challenges.

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Chemoenzymatic Cascades Combining Biocatalysis and Transition Metal Catalysis for Asymmetric Synthesis

Cited by 7 publications

References 148 publications

Organocatalytic hydration of activated alkynes

Organocatalytic hydration of activated alkynes

Merging Organolithium Chemistry and Stereoselective Biocatalysis: Transformation of Aromatic Nitriles into Chiral Alcohols

Design von 3D‐gedruckten heterogenen Reaktorsystemen zur Überwindung von Inkompatibilitätshürden bei der Kombination von Metall‐ und Enzym‐Katalyse in einem Eintopf‐Prozess

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